Assembly comprising an electric component

ABSTRACT

The invention relates to an assembly comprising an electric component. The component has an electric part, a control circuit, and a capacitor. At least two lead frames are provided which are embedded into a housing. The part, the control circuit, and the capacitor are arranged on the lead frames, and the control circuit is designed to charge the capacitor and to supply the part with current from the capacitor in a clocked manner. The component has two contacts, and the component is arranged on a support. The support has an electrically conductive layer and the two contacts are connected to the layer in an electrically conductive manner. At least one first part of one lead frame is arranged at a greater distance from the electrically conductive layer than the second lead frame.

RELATED APPLICATIONS

This application is a United States National Phase under 35 U.S.C. § 371of International Application No. PCT/EP2017/061736, filed on May 16,2017, which claims priority to German Patent Application No.102016208431.3, filed May 17, 2016, both of which are herebyincorporated by reference in their entirety for all purposes.

The invention relates to an arrangement having an electrical deviceaccording to claim 1 and to a method according to claim 9.

In the prior art arrangements having an electrical device, which isarranged on a carrier, are known.

The object of the invention is to provide an arrangement having anelectrical device which has improved electrical properties.

The object of the invention is achieved by the arrangement according toclaim 1 and by the method according to claim 9.

Further developments of the invention are described in the dependentclaims.

According to at least one embodiment, the electrical device comprises anelectrical component. The component is preferably a semiconductorcomponent which is designed to generate radiation. In particular, thecomponent is a light-emitting diode, LED for short, or a laser diode,abbreviated to LD. For example, the component is designed to emitradiation having a wavelength of maximum intensity of at least 360 nm or410 nm or 760 nm and/or of at most 1300 nm or 1050 nm or 570 nm. Inparticular, the component is designed to generate visible light ornear-infrared radiation.

According to at least one embodiment, the device comprises one or morecontrol circuits. The at least one control circuit is configured forpulsed operation of the component. A pulse duration which can beachieved overall by the control circuit and by the component, ispreferably at least 0.5 ns or 2 ns and/or at most 15 ns or 10 ns or 8ns. In particular, the pulse duration is at least 3 ns and/or at most 6ns. The pulse duration is understood to mean in particular the fullwidth at half the height of the maximum in the time domain, FWHM forshort.

According to at least one embodiment, the device comprises one or morecapacitors. The at least one capacitor is electrically connected inseries with the associated component and is configured for pulsedenergization of the component. A capacitance of the capacitor is, forexample, at least 10 nF or 30 nF and/or at most 1 μF or 0.5 μF. Inparticular, the capacitance is 100 nF. If a plurality of components arepresent for generating radiation, a separate capacitor can be assignedto each component. In order to reduce inductances, it is possible for aplurality of capacitors connected electrically in parallel to bepresent, also per component.

According to at least one embodiment, the device comprises a lead frameassembly. The lead frame assembly comprises a plurality of lead frameswhich are different from one another. The lead frames are produced, forexample, by means of cutting, etching and/or punching from asemi-finished product of the lead frame assembly. The individual leadframes are not connected to one another in one piece by a common, inparticular metallic material. The lead frame is produced in particularfrom a copper sheet or a silver sheet, wherein coatings can be present,for example, for increasing a reflectivity or for improving asolderability. A thickness or an average thickness of the individuallead frames is preferably at least 50 μm or 100 μm or 200 μm and/or atmost 1 mm or 0.5 mm.

According to at least one embodiment, the lead frame assembly is thinnedin places from a mounting side of the component. This means that, fromthe mounting side, material removal relative to the original lead framehas been done and/or the lead frame assembly lies only partially in themounting side.

In this way, the lead frame assembly is not to be electrically and/ormechanically contacted over its entire surface.

According to at least one embodiment, the device can besurface-mountable. This means that the device can be fastened by meansof surface mount technology or SMT for short. In particular, the deviceis a QFN device, wherein QFN stands for Quad Flat No lead.

In at least one embodiment, the surface-mountable electrical devicecomprises at least one electrical component for generating radiation, acontrol circuit for pulsed operation of the component and a capacitorfor energizing the component. The carrier for the aforementionedelements is a lead frame assembly having a plurality of different leadframes which are separate elements. The lead frame assembly is thinnedin places from a mounting side of the device so that the lead frameassembly lies only partially in the mounting side.

In particular QFN housings for short high-current pulses, especially foroperating semiconductor lasers having a capacitor and a control circuitsuch as a field-effect transistor or a user-specific integrated circuit,ASIC for short, in a housing, preferably have low inductance values inan electrical discharge path. This is difficult to realize withelectrically single-layer housing concepts and/or printed circuitboards.

One possibility for implementing are so-called microstrip lines. Insingle-layer housing concepts such as QFN components, an adaptation to aprinted circuit board is therefore to be ensured so that the housing,together with the circuit board, forms at least one microstrip line.This is possible in particular by means of a targeted deep etching ofthe lead frame assembly and of individual lead frames, also referred toas conductor frames. In this way, a low overall inductance can beachieved and, in addition, it is possible to dispense with multi-layerprinted circuit boards, which are to be provided by the user and/orhandler of the electrical device. For example, a reduction of the numberof layers by approximately 50% can be achieved, compared to the use ofconventional devices instead of the device described here.

According to at least one embodiment, the component is applied to afirst lead frame. For example, the component is connected with a cathodeelectrically directly and areally to the first lead frame.

According to at least one embodiment, the capacitor is applied to asecond lead frame by means of a first connection. As also for all othercomponents, the application preferably takes place by means of solderingor electrically conductive adhesive bonding.

According to at least one embodiment, the control circuit and thecapacitor are applied to a third lead frame by means of a secondconnection. It is possible for the third lead frame to be larger thanthe second lead frame, which in turn can be larger than the first leadframe.

According to at least one embodiment, the control circuit iselectrically connected directly to one or to a plurality of contactsurfaces, wherein the contact surfaces are preferably formed by arespective lead frame. Electrically directly connected in particularmeans that no or no significant electrical resistance or no other activeelectrical components such as diodes or transistors or capacitors orcoils are mounted in the current path. No significant electricalresistance can mean less than 2Ω or 0.5Ω.

According to at least one embodiment, the component is directlyelectrically connected to the second lead frame and to the controlcircuit.

An electrically direct connection can be realized, for example, by meansof soldering or electrically conductive adhesive bonding. An electricaldirect connection can also be realized by means of one or more bondingwires or one or more conductor tracks. If there are a plurality ofbonding wires and/or conductor tracks for the direct electricalconnection, they can thus be electrically connected in parallel in orderto achieve a low inductance at high currents.

The described device allows low inductances to be achieved, inparticular in the case of high-current pulses, for example in the orderof 30 A over 1 ns. The carrier to be provided by the user, such as aprinted circuit board or PCB for short, can be designed as asingle-layer or two-layer board, so that fewer layers are required incomparison with conventional devices. This makes it possible to achievea cost saving as well as a power increase and short pulses withparticularly high currents can be applied.

According to at least one embodiment, the second lead frame is designedas an external electrical contact point for a supply voltage. The supplyvoltage is, for example, at least 10 V or 15 V and/or at most 30 V or 20V.

According to at least one embodiment, the third lead frame is designedas an external electrical contact point for a ground contact, alsoreferred to as ground or GND. Alternatively, it is possible for thesecond lead frame to be in the form of a ground contact and the thirdlead frame serves as a contact for the supply voltage.

According to at least one embodiment, one of the contact surfaces, whichis electrically directly connected to the control circuit, is designedas an external electrical contact point for a control voltage. Thecontrol circuit can be switched to electrically conductive via thecontrol voltage, also referred to as a trigger. This means that thedevice is controlled via the control voltage. In particular, thecomponent emits only radiation when the control voltage is applied.

According to at least one embodiment, during operation of the component,a current flows from the capacitor via the second lead frame to thecomponent and from there to the first lead frame and from there to thethird lead frame. A connection between the lead frames is in particularrealized in each case by a plurality of parallel bonding wires.

According to at least one embodiment, the second and the third leadframe are L-shaped when viewed in plan view. Thus, the second lead frameis preferably located within a rectangle spanned by the third leadframe.

According to at least one embodiment, the device comprises a housing.The housing is preferably made of one or more plastics. The individuallead frames of the lead frame assembly are mechanically connected to oneanother by means of the housing. The component is mechanicallystabilized via the housing. It is possible for a material of the housingto partially form the mounting side. The mounting side can consist ofthe lead frames and the housing material.

According to at least one embodiment of the device, the third lead frameis the largest lead frame. The size of the second lead frame can liebetween the sizes of the first and third lead frames. This applies, inparticular, in a plan view.

According to at least one embodiment, the first and/or the third leadframe are T-shaped when viewed in plan view. In this case, middle partsof the two T's can point towards each other. The middle part is in thiscase the centrally located part projecting from a continuous upper part.The middle parts are preferably shorter than the upper parts.

According to at least one embodiment, the second lead frame, viewed in aplan view, lies between the first and the third lead frame. The secondlead frame preferably lies on a side of the two middle parts of the T's.

The invention further relates to an arrangement. The arrangementpreferably comprises one or more devices as indicated in connection withone or more of the above-mentioned embodiments. Features for the deviceare therefore also disclosed for the arrangement and vice versa.

In at least one embodiment, the arrangement comprises a carrier, on thetop side of which the at least one device is applied. On the top side,there is a contact layer with one or, preferably, a plurality of contactpoints for electrically and mechanically contacting the device. At leastsome of the lead frames are electrically and mechanically connected tothe contact points, wherein this does not have to apply to all the leadframes of the device. The lead frames are partially spaced apart fromthe top side of the carrier.

According to at least one embodiment, a first region of the third leadframe, on which the control circuit and the capacitor with the secondconnection are applied, is electrically directly connected to a secondregion of the third lead frame via the contact layer. These two regionsof the third lead frame are preferably spatially separated from oneanother and are located in particular on opposite, most distant regionsof the lead frame. The two regions can be separated from one anotherexclusively with regard to their electrical function, so that no real,physical boundary between the regions needs to exist.

According to at least one embodiment, during operation of the component,both connections of the capacitor are electrically connected to oneanother via the component, the control circuit and the contact layer. Asa result, it is possible that an inductance for a discharge current ofthe capacitor is reduced and a part of the discharge current flowsthrough the contact layer of the carrier. The discharge current throughthe contact layer preferably runs congruently or approximatelycongruently with the current flow through the component.

In other words, a type of mirror current to the discharge currentthrough the component in the device can be realized in the contact layerof the carrier. As a result, magnetic fields occurring due to thecurrents can be at least partially compensated so that overall aninductance is effectively reduced. In this way, shorter switching timesand/or larger discharge currents can be realized.

According to at least one embodiment of the arrangement, duringoperation of the component both connections of the capacitor areelectrically connected to one another via the component, the controlcircuit and the third lead frame. This means that a part of thedischarge current also flows within the device. Said discharge pathwithin the device is electrically connected in parallel to the dischargepath via the contact layer. Here and otherwise, “discharge current”means in particular that a side of the capacitor facing away from thecomponent is supplied with current during discharging.

According to at least one embodiment, the contact layer, which connectsthe first and second regions to one another, runs completely andpreferably directly on the top side of the carrier. The contact layercan be designed to be flat. In particular, the contact layer extendsover the whole area under the first lead frame, but electricallyinsulated therefrom. For this purpose, the first lead frame ispreferably spaced apart from the mounting side. This can be achieved bya whole-area thinning of the first lead frame. Alternatively, thecontact layer can lie within or on an underside of the carrier or can berealized by a plurality of layers in the carrier.

According to at least one embodiment, the second lead frame, viewed in aplan view, lies in parts over the contact layer. Due to the point-wisethinning of the second lead frame, the latter is spaced apart from thecontact layer in the regions mentioned. This design of the second leadframe makes it possible that the discharge current in the contact layeris congruent or approximately congruent with the current across thecomponent, viewed in a plan view. At the same time, the second leadframe can be electrically contacted via another contact point of thecontact layer of the carrier.

According to at least one embodiment, a distance between the contactlayer and the first lead frame on which the component is located is atmost 1.5 mm or 1 mm or 0.5 mm. Alternatively or additionally, thisdistance is at least 0.1 mm or 0.2 mm. This distance ensures, on the onehand, a short-circuit safety, on the other hand low effectiveinductances can be achieved due to the compensation of the dischargecurrent in the contact layer of the carrier and of the discharge currentthrough the component.

The invention further relates to an arrangement comprising an electricaldevice wherein the device has an electronic component, a control circuitand a capacitor, wherein at least two lead frames are provided, whereinthe lead frames are embedded in a housing, and wherein the component,the control circuit and the capacitor are arranged on the lead frame,wherein the control circuit is configured to charge the capacitor,wherein the control circuit is configured to supply the component in aclocked manner with current from the capacitor, wherein the device hastwo contacts, wherein the device is arranged on a carrier, wherein thecarrier has an electrically conductive layer, wherein the two contactsare electrically conductively connected to the layer, wherein at least afirst part of a lead frame has a greater distance from the electricallyconductive layer than a second part of the lead frame. A betterelectrical insulation is achieved by the greater distance between atleast a part of the first lead frame and the electrically conductivelayer.

In one embodiment, the first lead frame has a greater distance from thelayer than the second and/or further lead frame. As a result, a furtherimproved electrical insulation of the entire first lead frame is madepossible.

In one embodiment, upper sides of the lead frames are arranged at thesame height. As a result, a simple construction is made possible. Due tothe thinner design of at least the part of the first lead frame, thethickness of the part of the first lead frame can lie in a range of 90%to 50% or less of the thickness of the rest of the first lead frame.

In one embodiment, three lead frames are provided, wherein the componentis electrically conductively connected to the first lead frame by meansof a first connection, wherein the component is connected to the secondlead frame by means of a second connection, wherein the capacitor iselectrically conductively connected to the second lead frame by means ofa first connection, wherein the capacitor is connected to the third leadframe by means of a second connection, wherein the control circuit isconnected to the first lead frame by means of a first connection,wherein the control circuit is connected to the second lead frame bymeans of a second connection, wherein the control circuit is connectedto the third lead frame by means of a third connection, and wherein thetwo contacts are connected to the third lead frame. A compact structureis thus obtained.

In one embodiment, the component is arranged on the first lead frame,wherein the capacitor is arranged on the second and third lead frames,and wherein the control circuit is arranged on the third lead frame.

In one embodiment, an insulating layer is introduced into the carrierbetween the part of the lead frame which is further away from the layerand the carrier. As a result, a further improvement of the electricalinsulation is achieved.

In one embodiment, a second electrically conductive layer is arranged inthe carrier, wherein the second layer is electrically conductivelyconnected to the first layer, and wherein the first and the secondlayers are arranged parallel to one another. As a result, the electricalresistance for the return flow in the carrier is reduced.

In one embodiment, the component is configured as a light-emittingcomponent. The compact structure described is advantageous in particularin the case of light-emitting properties.

The invention further relates to a method for producing such a deviceand/or such an arrangement. Features of the method are therefore alsodisclosed for the device and the arrangement and vice versa.

Thus, a method for producing an arrangement is proposed, wherein a firstand at least one further lead frame are provided, wherein at least apart of the first lead frame is formed thinner from a bottom side thanthe further lead frame, wherein the lead frames are embedded in amaterial, in particular in a molding material, wherein a capacitor, acomponent and a control circuit are mounted on the lead frames and adevice is obtained, wherein a carrier having an electrically conductivelayer is provided, wherein the device is mounted on the carrier with adevice underside, wherein the further lead frame is electricallyconductively connected to the layer via two contacts.

The thinner formation of at least the part of the first lead frame iseffected in particular by etching the first lead frame from theunderside. Due to the thinner design of at least the part of the firstlead frame, the thickness of the part of the first lead frame can lie ina range of 90% to 50% or less of the thickness of the rest of the firstlead frame.

According to at least one embodiment of the method, at least a part ofthe first lead frame is formed thinner from the underside by means ofdeep etching. The same applies to the second lead frame and can alsoapply to the third lead frame with regard to small surface portions.

According to at least one embodiment, the entire first lead frame isformed thinner than the further lead frame.

The above-described properties, features and advantages of thisinvention, and the manner in which they are achieved, become clearer andmore precisely understandable in connection with the followingdescription of the exemplary embodiments, which are explained in moredetail in connection with the drawings. In the Figures:

FIG. 1 shows a perspective illustration of the arrangement,

FIG. 2 shows a plan view of the arrangement of FIG. 1,

FIG. 3 shows a schematic illustration of an electrical equivalentcircuit of the arrangement,

FIG. 4 shows a schematic cross section through the arrangement of FIG.1,

FIG. 5 shows a schematic cross section through a further embodiment of acarrier,

FIG. 6 shows a further exemplary embodiment of a device described here,and

FIG. 7 shows a further schematic illustration of an electricalequivalent circuit of the arrangement.

FIG. 1 shows a perspective view of an arrangement having an electricaldevice 1 which is arranged on a carrier top side 22 of a carrier 2. Inthe exemplary embodiment illustrated, the device 1 has three lead frames3, 4, 5. The three lead frames 3, 4, 5 are spaced apart from one anotherand are embedded in an electrically insulating housing 6 and aremechanically connected to one another by the housing 6. The device 1 isthus a QFN device. A mounting side 41 of the surface-mountable device 1preferably consists of the lead frames 3, 4, 5, 10, 11, 12, 13 and ofthe housing 6.

Arranged on the first lead frame 3 is an electrical component 7, inparticular a laser diode that can be operated in a pulsed manner. Inaddition, a capacitor 8 is provided, which is partially arranged on thesecond and on the third lead frames 4, 5. Furthermore, a control circuit9 is provided which is arranged on the third lead frame 5. In addition,four contact surfaces 10, 11, 12, 13 are embedded in the housing 6,wherein the contact surfaces 10, 11, 12, 13 are likewise realized in theform of lead frames. The carrier 2 has an electrically conductive layer14 (not shown in FIG. 1) which is divided into a plurality of contactpoints in order to contact at least a part of the lead frames 3, 4, 5,10, 11, 12, 13 electrically and mechanically. The lead frames 3, 4, 5,10, 11, 12, 13 form a lead frame assembly 40.

The component 7 can, for example, be in the form of an electricalcomponent such as, for example, a transistor, in the form of an electriccircuit and/or in the form of a light-emitting component. In theexemplary embodiment illustrated, the component is in the form of alight-emitting component, in particular in the form of a laser or alaser diode, which radiates light in a lateral emission direction 15.The component 7, the capacitor 8 and the control circuit 9 arepreferably covered with an insulation layer 16. The insulation layer 16can be transparent and transmissive to the radiation generated duringoperation.

FIG. 2 shows a schematic representation of a view from above of thearrangement of FIG. 1. The component 7 is electrically conductivelyconnected to the first lead frame 3 by means of a first connection 17,as shown in cross section view of FIG. 4. In addition, the component 7is electrically conductively connected to the second lead frame 3 bymeans of a second connection 18. The first connection 17 can be formed,for example, of contacts on the underside of the component 7. The secondconnection 18 can be designed in the form of bonding wires. In adeparture from the illustration in FIGS. 1 and 2, a plurality ofparallel-connected bonding wires are preferably present, fourelectrically parallel bonding wires, for example, in order to be able torealize shorter switching times.

As in all other exemplary embodiments, it is also possible that thecomponent 7 is not arranged on a separate lead frame 3, but is locatedon the second lead frame 4 together with the first connection 23 of thecapacitor 8, or alternatively also on the third lead frame 5 togetherwith the second connection 24.

The control circuit 9 is electrically conductively connected with itsfirst connection 19 to the first lead frame 3, for example by means ofbonding wires. In addition, the control circuit 9 is electricallyconductively connected with its second connection 20 to the second leadframe 4, for example by means of bonding wires. A short-circuit currentor a precharge of the capacitor 8 and/or of the component 7 can beeffected via the second connection 20. If the control circuit 9 is an ICor ASIC, and not just a transistor such as a FET, in addition a controlof the voltage applied to the second lead frame 4 can also take placevia the second connection 20. It is thus possible in particular forerror signals to be output via the control circuit 9, for example viathe contact surfaces 10, 12, 13. One of the contact surfaces 11 isprovided for a trigger signal T for switching the component 7, the othercontact surfaces 10, 12, 13 can be functionalized for additionalsignals.

Furthermore, the control circuit 9 is electrically conductivelyconnected to the third lead frame 5 via a third connection 21, forexample in the form of bonding wires. In addition, the control circuit 9is electrically conductively connected to the contact surfaces 10, 11,12, 13 via further connections 220.

The capacitor is electrically conductively connected with its firstconnection 23 to the second lead frame 4. In addition, with its secondelectrical connection 24 the capacitor 8 is electrically conductivelyconnected to the third lead frame 5. The first and the secondconnections 23, 24 of the capacitor 8 can be designed, for example, inthe form of bonding wires or in the form of contacts on the underside ofthe capacitor 8.

In addition, the third lead frame 5 is electrically conductivelyconnected via two contacts 25, 26, which are drawn in dashed lines, tothe electrically conductive layer 14 of the carrier 2. A first region 25is arranged in FIG. 2 on a lefthand side next to the control circuit 9.A second region 26 is arranged near the capacitor 9. The layer 14 islikewise drawn in dashed lines. The layer 14 can have a flat, inparticular rectangular shape. The layer 14 can extend over a large partof the surface of the carrier 2.

In addition, the layer 14 is structured into contact points for the leadframes 4, 10, 11, 12, 13, not shown. In this case, the first lead frame3 is spaced apart from the layer 14 and is not directly contacted withthe latter. The second lead frame 4 is only partially in contact withone of the contact points of the layer 14, seen in plan view, so that noshort circuit occurs with the third lead frame 5.

The control circuit 9 is connected via the carrier 2 to a current source(not illustrated) and is configured in order to charge the capacitor 8via the second and third connections 20, 21. In addition, the controlcircuit 9 is designed to electrically conductively connect the component7 to the capacitor 8 via the layer 14 by means of the first and thirdconnections 19, 21. Thus, current flows from the first connection 23 ofthe capacitor 8 via the second lead frame 4, the component 7, the firstlead frame 3, the first connection 19 of the control circuit 9 and thethird connection 21 of the control circuit 9 via the first contact 25into the electrically conductive layer 14 of the carrier 2. Proceedingfrom the first contact 25, the current flows in the layer 14 back to thesecond contact 26 to the second connection 24 of the capacitor 8.

Between the capacitor 8, the component 7 and the control circuit 9, thecurrent flows above the carrier 2 in the direction represented by afirst arrow 31, within the device 1. The inductive return flow of thecurrent, that is to say the discharge path, takes place on the basis ofthe inductive resistance in the layer 14 in a similar way, which isindicated with the aid of a second arrow 32. The preferably flat layer14 thus enables an electrical return of the current with a lowinductance. As a result, for example, short current pulses of 30 A canbe transmitted with a time duration of 1 ns.

Such devices 1 which can generate short radiation pulses can be used,for example, for distance measurements, also referred to astime-of-flight applications or ToF applications.

Depending on the selected design, the layer 14 could also be formed in aU-shaped manner with two limbs and a transverse connection, wherein thecontacts 25, 26 are arranged in the end regions of the limbs and thetransverse connection is arranged in the region of the component 7. TheU-shape is aligned in accordance with the second arrow 32, since theinductive current flow in the second layer 14 is effected via this path.

FIG. 3 shows a schematic illustration of an electrical equivalentcircuit diagram of the current flow during operation of the component 7,which is designed, for example, as a laser diode.

A supply voltage V is applied to the second connection 20 of the controlcircuit 9. Furthermore, the control circuit 9 is connected to a controlvoltage T, via which a switching element in the control circuit 9, suchas a field-effect transistor, FET for short, can be opened and closed.The third lead frame 5 is connected to a ground contact GND via thecorresponding contact point of the layer 14.

If the switching element is open, so that no current flows via theswitching element, the capacitor 8 will be charged. In this way, none ofthe currents 31, 32 then flows.

If the switching element is closed, the capacitor is discharged in oneshort current pulse via the component 7 and the switching element 9towards the ground contact GND, so that the first discharge current 31flows within the device 1. Since an electric charge flows away from aside of the capacitor 8 that is electrically facing the component 7, inorder to compensate for an electrical charge at the same time anelectrical charge has to flow to the side of the capacitor 8 which iselectrically remote from the component 7. This takes place by means ofthe second discharge current 32. The second discharge current 32 runs ina design-dependent manner, in particular predominantly in the layer 14of the carrier 2, and runs, as illustrated in connection with FIG. 2 ina plan view, preferably approximately congruent with the first dischargecurrent 31, only in the opposite direction. Due to this counter-currentflow, a lower effective inductance can be achieved.

In addition to the current flow 32 through the layer 14, a current flow33 can also take place directly in the third lead frame 5. This meansthat the currents 32, 33 can be parallel, as a result of which theeffective inductance can be further reduced. In addition, as a result ofthe connection via the third lead frame 5, the device 1 can also beoperated without the carrier 2, in particular for test purposes and/orfor production control.

FIG. 4 shows a schematic illustration of a cross section through thearrangement of FIG. 1, wherein not all contact points of the layer 14and also not all the lead frames 3, 4, 5, 10, 11, 12, 13 are shown. Inthis embodiment, the electrically conductive layer 14 is arrangeddirectly on the top side of the carrier 2. The third lead frame 5 iselectrically conductively connected to the layer 14 via the contacts 25,26. The first and the second lead frames 3, 4 have a smaller thicknessat least in places than the third lead frame 5. The thickness of thefirst and of the second lead frames 3, 4 can lie in the range of 90% to50% or less of the thickness of the third lead frame 5.

In addition, the first and the second lead frames 3, 4 are arranged withan upper side facing away from the carrier 2 at the same height as thethird lead frame 5. In this way, the first and the second lead frames 3,4 are at a greater distance from the electrically conductive layer 14.An improved electrical insulation is thus obtained between the first andthe second lead frames 3, 4 and the electrically conductive layer 14.Better electrical insulation is also achieved when at least a part ofthe first lead frame 3 and/or of the second lead frame 4 is at a greaterdistance from the layer 14.

In the exemplary embodiment illustrated, between the layer 14 and thefirst and the second lead frames 3, 4 an insulation layer 27 isarranged. The insulation layer 27 preferably forms a part of the housing6 and is designed in particular in one piece with the remaining parts ofthe housing 6 and can consist, for example, of a polymer or, lesspreferably, of a photoresist. Depending on the selected embodiment, theinsulation layer 27 can be dispensed with so that between the layer 14and the lead frames 3 a gas such as air or an evacuated region islocated at least in places. A further improved electrical insulationbetween the first and the second lead frames 3, 4 can be achieved withthe aid of the insulation layer 27 and the layer 14. The first and thesecond contacts 25, 26 can be formed, for example, as a contact layer.The carrier 2 can be designed, for example, as a conductor plate and/ora PCB (printed circuit board).

In addition, the layer 14, as shown schematically in FIG. 5, can also bearranged in the carrier 2. Furthermore, the layer 14 can also bearranged on an underside of the carrier 2 facing away from the device 1.In addition, a further layer 28 can be arranged in the carrier 2, saidfurther layer being arranged parallel to the layer 14. By the provisionof a further layer 28, which forms an electrically conductive connectionbetween the first and the second contacts 25, 26, in or on the carrier2, the electrical resistance is further reduced, as a result of whichshorter switching times can be realized.

The layers 14, 28 are preferably connected via electrically conductivevia contacts 29, 30 in or on side faces of the carrier 2 and areelectrically conductively connected to the contacts 25, 26.

The lead frames 3, 4, 5 are produced from an electrically conductivematerial, in particular from copper or a copper alloy. Coatings can bepresent, for example for improving a solderability. The first lead frame3 is completely etched and the second lead frame 4 is partially etchedwith the aid of an etching process, for example, from the mounting side41, to a smaller thickness than the third lead frame 5. The first andthe second lead frames 3, 4 can thus be produced with the aid of deepetching of a QFN lead frame.

With the aid of the described arrangement, a microstrip line is realizedin the carrier 2 by means of the correspondingly shaped layer 14 and inparticular its contact point for the third lead frame 5, wherein thelayer 14 and/or the further layer 28 preferably represent a groundplane.

Improved electrical properties are already achieved if only the firstlead frame 3 or only the second lead frame 4 has a smaller thicknessand/or a greater distance to the layer 14 of the carrier 2.

Furthermore, an improvement in the electrical properties is achievedwhen a part of the first or of the second lead frame 3, 4 is at agreater distance from the layer 14. A reduction in the inductance isbetter the smaller the distance between the lead frames 3, 4 and the GNDlayer 14. However, the distance between the lead frames 3, 4 and thelayer 14 is required in order to prevent an electrical short circuit.

The first, the second and the third lead frames 3, 4, 5 are, forexample, produced in that a lead frame grid having first, second andthird lead frames is manufactured from a metal part, in particularcopper. In this case, at least one part of the first and/or of thesecond lead frame 3, 4 or the entire first and the second lead frames 3,4 is produced with a thinner thickness, wherein the upper side of thefirst and of the second lead frames 3, 4 is at the same height as theupper side of the third lead frame 5.

For producing the lead frames, an etching method can be used, forexample. In this case, the first and/or the second lead frame are formedthinner from the underside than the third lead frame 5, for example witha depth etching. Subsequently, the lead frames 3, 4, 5 are embedded in amolding material, for example made of plastic material for the housing6. The capacitor 8, the component 7 and the control circuit 9 are placedon the lead frames 3, 4, 5 and, as described above, are electricallyconductively connected to the lead frames. Subsequently, saidarrangement is separated out of the composite. During the separation,connecting webs between the lead frames 3, 4, 5, 10, 11, 12, 13 are cutthrough, corresponding end faces of the lead frames 3, 4, 5, 10, 11, 12,13 can lie freely on the outside of the housing 6, see also FIGS. 1 and6E. The device 1 is thus obtained. The device 1 can now be electricallyconductively connected to the carrier 2, as already explained above. Inaddition, however, the device 1 can also be supplied separately to acustomer and can just be installed by the customer with the carrier 2.

With the aid of the described method, a device 1 and an arrangementhaving a device 1 and a carrier 2 can be produced in a simple andcost-effective manner.

Due to the one-sided stronger thinning of at least one part of the firstand of the second lead frames 3, 4 or of the entire lead frames 3, 4, adevice 1 is obtained in which the upper sides of the lead frames 3, 4, 5are arranged at the same height. In this way, the capacitor 8, thecontrol circuit 9 and the component 7 are mounted in a simple andprecise manner on the lead frames 3, 4, 5. At the same time, however, atleast a part of or the entire first and second lead frames 3, 4 are setback with their underside with respect to a lower side of the third leadframe 5, the lower side of which faces the carrier 2. Thus, whenmounting the device 1 to the mounting side 41 on the carrier 2, anenlarged distance between the carrier 2 and at least part of the firstand second lead frames 3, 4 is obtained. Hence, an arrangement having animproved electrical insulation between the layer 14 of the carrier 2 andthe first and/or second lead frames 3, 4 can be provided. In addition,an insulating layer can be introduced between the carrier 2 and thethinner first and/or second lead frames, in order to improve theelectrical insulation.

Depending on the selected embodiment, the device 1 can also have onlytwo lead frames 3, 4. In this embodiment, at least a part of theunderside of one of the two lead frames is set back in relation to theunderside of the other lead frame. In this embodiment, too, anarrangement comprising a component and a carrier can be provided, inwhich the electrical insulation between one of the lead frames and anelectrically conductive layer of the carrier is improved.

FIG. 6 illustrates a further exemplary embodiment of the device 1, seethe plan views in FIGS. 6A and 6B, the side views in FIGS. 6C and 6D andthe sub-views in FIGS. 6E and 6F. For better identification, FIGS. 6B,6D and 6F are drawn without the housing 6. The representations in FIG. 6are to scale, dimensional specifications are given in mm.

In this exemplary embodiment, the third lead frame 5 is the largest leadframe. In addition, five of the contact surfaces 10, 11, 12, 13 arepresent, wherein, in contrast to this, more or fewer contact surfacescan also be provided. Both the first and the third lead frames 3, 5 areT-shaped when viewed in plan view, wherein comparatively short-shapedmiddle parts of the T's each point to the other lead frame 3, 5. Thesecond lead frame 4, which is in particular designed as ground contactGND, is located between the lead frames 3, 5.

The third lead frame 5 is thus preferably designed as a contact for thesupply voltage V. Such a transposition of the contacts V, GND relativeto FIG. 1 can also occur in all other exemplary embodiments.

The first lead frame 3 with the component 7 is preferably notelectrically connected, but is used, for example, only as a heat sink.The third lead frame 5 separates the lead frames 3, 4 spatially from thecontact surfaces 10, 11, 12, 13, seen in a plan view. The capacitor 8 islocated as close as possible to the middle parts of the T's of the leadframes 3, 5. The lead frames 3, 4, 5, 10, 11, 12, 13 and the elements 7,8, 9 are each electrically connected by means of bonding wires.

Otherwise, the statements relating to FIGS. 1, 2, 4 and 5 apply.

In FIG. 7, the electrical circuitry is sketched analogously to FIG. 3.In contrast to FIG. 3, the switching element of the control circuit 9 iselectrically arranged between the component 7 and the capacitor 8.Optionally, as in FIG. 3, not shown in FIG. 7, a path for the thirddischarge current can be provided in the device 1, in particular in thethird lead frame 5. Otherwise, the statements relating to FIG. 3 apply.

Although the invention has been illustrated and described in more detailby the preferred exemplary embodiment, the invention is not restrictedby the disclosed examples and other variations can be derived from theperson skilled in the art, without departing from the scope ofprotection of the invention.

This patent application claims the priority of German patent application10 2016 208 431.3, the disclosure content of which is herebyincorporated by reference.

LIST OF REFERENCE SIGNS

-   1 device-   2 carrier-   22 carrier top side-   40 lead frame assembly-   3 first lead frame-   4 second lead frame-   5 third lead frame-   6 housing-   7 component-   8 capacitor-   9 control circuit-   10 first contact surface-   11 second contact surface-   12 third contact surface-   13 fourth contact surface-   14 layer-   15 emission direction-   16 insulation layer-   17 first connection of the component-   18 second connection of the component-   19 first connection of the control circuit-   20 second connection of the control circuit-   21 third connection of the control circuit-   220 further connection-   23 first connection of the capacitor-   24 second connection of the capacitor-   25 first contact-   26 second contact-   27 insulation layer-   28 further layer-   29 first via contact-   30 second via contact-   31 first arrow/first discharge current in the device-   32 second arrow/second discharge current in the carrier-   33 third arrow/third discharge current in the device-   41 mounting side-   100 arrangement-   GND ground contact-   T control voltage-   V supply voltage

The invention claimed is:
 1. An arrangement having a surface-mountableelectrical device and having a carrier, the surface-mountable electricaldevice comprising at least one electrical component which is asemiconductor component and which is intended for generating radiation,a control circuit for pulsed operation of the component, a capacitorwhich is connected to the component electrically in series and which isconfigured for the pulsed energization of the component, and a leadframe assembly as a mounting platform for the component, the capacitorand the control circuit, wherein the lead frame assembly comprises aplurality of different lead frames including at least a first leadframe, a second lead frame, and a third lead frame, and at least one ofthe plurality of different lead frames is thinner than at least oneother of the lead frames of the plurality of different lead frames sothat the lead frame assembly lies only partially in a mounting side,wherein the device is applied to a top side of the carrier, a contactlayer having a plurality of contact points is present on the top side,and the lead frames are electrically and mechanically connected to saidcontact points, and the lead frames are partially spaced apart from thetop side, wherein a first region of the third lead frame, on which thecontrol circuit and the capacitor are arranged, is electricallyconnected directly to a second region of the third lead frame via thecontact layer, wherein during operation of the component bothconnections of the capacitor are electrically connected to one anothervia the component, the control circuit and the contact layer such thatby means of the contact layer an inductance for a discharge current outof the capacitor is decreased and a part of the discharge current flowsthrough the contact layer.
 2. The arrangement device according to claim1, wherein the component is mounted on the first lead frame, thecapacitor is applied to the second lead frame by means of a firstconnection, the control circuit and the capacitor are connected to asecond connection on the third lead frame, the control circuit iselectrically connected directly to at least one contact surface which isformed by one of the lead frames, the component is electricallyconnected directly to the second lead frame and the control circuit. 3.The arrangement according to claim 2, wherein the second lead frameserves as an external electrical contact point for a supply voltage (V)and the third lead frame is configured as an external electrical contactpoint for a ground contact (GND), at least one of the contact surfacesis configured as an exposed electrical contact point for a controlvoltage (T) for the control circuit, and the component lies electricallybetween the capacitor and the control circuit, or the control circuitlies electrically between the component and the capacitor.
 4. Thearrangement according to claim 2, wherein the second and the third leadframes are L-shaped when viewed in a plan view, wherein the second leadframe lies within a rectangle spanned by the third lead frame.
 5. Thearrangement according to claim 2, wherein the third lead frame is thelargest lead frame and the first and the third lead frames are T-shapedwhen viewed in a plan view, so that middle parts of the two T's faceeach other, wherein the second lead frame is arranged between the firstand the third lead frames on one side of the two middle parts of the T'swhen viewed in a plan view.
 6. The arrangement according to claim 1,further comprising a housing, wherein the housing is made of a plasticand the housing is partially located between the lead frame assembly andthe mounting side, and wherein the device is a QFN device.
 7. Thearrangement according to claim 1, wherein during operation of thecomponent the two connections of the capacitor are electricallyconnected to one another via the component, the control circuit and thelead frame so that a part of the discharge current flows within thedevice.
 8. The arrangement according to claim 1 wherein the contactlayer-which connects the first and second regions runs completely anddirectly on the top side, wherein the first lead frame is spaced apartfrom the mounting side and has been thinned over the whole area by athinning process, and wherein the second lead frame, viewed in planview, is arranged in places above the contact layer and is spaced apartfrom the contact layer as a result of a point-wise thinning process. 9.An arrangement having a surface-mountable electrical device and having acarrier, the surface-mountable electrical device comprising at least oneelectrical component which is a semiconductor component and which isintended for generating radiation, a control circuit for pulsedoperation of the component, a capacitor which is connected to thecomponent electrically in series and which is configured for the pulsedenergization of the component, and a lead frame assembly having aplurality of different lead frames as a mounting platform for thecomponent, the capacitor and the control circuit, wherein the lead frameassembly comprises a lead frame that is thinner than at least one otherlead frame of the plurality of different lead frames so that the leadframe assembly lies only partially in a mounting side, wherein thedevice is applied to a top side of the carrier, a contact layer having aplurality of contact points is present on the top side, and the leadframes are electrically and mechanically connected to said contactpoints, and the lead frames are partially spaced apart from the topside, wherein in a plan view, a discharge current in the device throughthe component is congruent with the discharge current in the contactlayer, wherein a distance between the contact layer and a first leadframe of the plurality of lead frames on which the component is locatedis at most 1.5 mm.
 10. The arrangement according to claim 1, whereinupper sides of the lead frames facing away from the mounting side arearranged at the same height.
 11. The arrangement according to claim 1,wherein a second electrically conductive layer is arranged in thecarrier, wherein the second layer is electrically conductively connectedto the first layer, and wherein the first and the second layers arearranged parallel to one another.
 12. A method for producing thearrangement according to claim 1, wherein a first and at least onefurther lead frame are provided, wherein at least a part of the firstlead frame is subjected to a thinning process such that the first leadframe is thinner than the at least one further lead frame so that thelead frame assembly lies only partially in the mounting side, whereinthe lead frames are embedded in a material for a housing, wherein thecapacitor, the component and the control circuit are mounted on the leadframes, wherein an underside of a part of the first lead frame is at agreater distance from the mounting side of the device than at least onepart of the at least one further lead frame, and wherein the device ismounted on the carrier top side.
 13. The method according to claim 12,wherein the thinning process to which the first lead frame is subjectedcomprises a deep etch so that a thickness of the first lead frame isbetween 50% and 90% inclusive of a thickness of the at least one furtherlead frame.